Advanced Phase Change Composite by Thermally Annealed Defect-Free Graphene for Thermal Energy Storage

Xin, Guoqing; Sun, Hongtao; Scott, Spencer; Yao, Tiankai; Lu, Fengyuan; Shao, Dali; Hu, Tao; Wang, Gongkai; Ran, Guang; Lian, Jie

doi:10.1021/am503619a

Cited by 121 publications

(62 citation statements)

References 47 publications

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“…Compared to monolayer graphene, graphene nanoplatelets (GNPs) are formed by several layers of graphene and are less prone to agglomeration and entanglement because of the increased thickness of up to approximately 100 nm [19]. By contrast to graphene oxide (GO), graphene nanoplatelets (GNPs) have emerged as a competitive, alternate material for graphene because thermal annealing or chemical treatment can eliminate functional groups on GO to produce GNPs [19,20]. Furthermore, in comparison with carbon nanotubes (CNTs) for which only one side of the atomic lattice contacts the matrix and the other side of the lattice faces into the center of the tube, both faces of graphene contact the matrix.…”

Section: Introductionmentioning

confidence: 99%

Graphene nanoplatelet-fly ash based geopolymer composites

Ranjbar

Mehrali

Sadeghinezhad

et al. 2015

Cement and Concrete Research

268

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Section: Introductionmentioning

confidence: 99%

Graphene nanoplatelet-fly ash based geopolymer composites

Ranjbar

Mehrali

Sadeghinezhad

et al. 2015

Cement and Concrete Research

268

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“…57,58 When octadecanol was inltrated into this carbon aerogel, the phase change process was inuenced, due to a disturbance to the crystal structure of the PCM by the aerogel, which implied a novel strategy for altering the phase change temperature of PCMs. 57,58 When octadecanol was inltrated into this carbon aerogel, the phase change process was inuenced, due to a disturbance to the crystal structure of the PCM by the aerogel, which implied a novel strategy for altering the phase change temperature of PCMs.…”

Section: Introductionmentioning

confidence: 99%

Nanoconfinement of phase change materials within carbon aerogels: phase transition behaviours and photo-to-thermal energy storage

2014

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We systematically investigated the thermal energy storage properties and host-guest interactions in a phase change composite based on octadecanol/carbon aerogels. Due to the nanoconfinement effect induced by the carbon aerogels, the loaded active materials show distinct phase transition behaviour to the free octadecanol, in which the solid-to-solid and solid-to-liquid phase change processes occurred at a lower temperature and the interval between these two processes became larger. † Electronic supplementary information (ESI) available: For the DSC results of pure octadecanol, and the IR spectra of the composite and pure octadecanol. See

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“…Introducing nanoscale or micron‐sized carbon materials as fillers is the most frequently used way to improve Κ PCM . Carbon nanomaterials, such as graphite nanoplatelets (GNPs), multilayer graphene (MLG), and graphene, are obtained by mechanically cleaving or chemically exfoliating the layered van der Waals (vdW) material of graphite flakes and generally have a high aspect ratio and ultrahigh intrinsic in‐plane TC ( Κ > 1500 W m −1 K −1 at room temperature) . The thermal conductivity enhancement (TCE, TCE = ( Κ comp – Κ PCM )/ Κ PCM ) is mainly dependent on the filler loading, interface thermal resistance between filler and PCM, and the geometric and dimensional properties of the filler including lateral size, thickness, and sheet orientation .…”

mentioning

confidence: 99%

“…To investigate the size effect of the graphite sheet on the TCE, we first compared the TCs of different compressed graphite blocks made from WEG and WEG ultrasonically pulverized for 15, 30, and 60 min (named as 15‐WEG, 30‐WEG, and 60‐WEG). The ultrasonic treatment destroys the vdW interactions between adjacent GNPs and is generally used to further exfoliate WEG into individual GNPs or MLG . The average length and diameter of raw WEG are 2.2 and 0.5 mm, respectively (Figure S6, Supporting Information).…”

mentioning

confidence: 99%

High‐Performance Thermally Conductive Phase Change Composites by Large‐Size Oriented Graphite Sheets for Scalable Thermal Energy Harvesting

et al. 2019

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Efficient thermal energy harvesting using phase‐change materials (PCMs) has great potential for cost‐effective thermal management and energy storage applications. However, the low thermal conductivity of PCMs (KPCM) is a long‐standing bottleneck for high‐power‐density energy harvesting. Although PCM‐based nanocomposites with an enhanced thermal conductivity can address this issue, achieving a higher K (>10 W m−1 K−1) at filler loadings below 50 wt% remains challenging. A strategy for synthesizing highly thermally conductive phase‐change composites (PCCs) by compression‐induced construction of large aligned graphite sheets inside PCCs is demonstrated. The millimeter‐sized graphite sheet consists of lateral van‐der‐Waals‐bonded and oriented graphite nanoplatelets at the micro/nanoscale, which together with a thin PCM layer between the sheets synergistically enhance KPCM in the range of 4.4–35.0 W m−1 K−1 at graphite loadings below 40.0 wt%. The resulting PCCs also demonstrate homogeneity, no leakage, and superior phase change behavior, which can be easily engineered into devices for efficient thermal energy harvesting by coordinating the sheet orientation with the thermal transport direction. This method offers a promising route to high‐power‐density and low‐cost applications of PCMs in large‐scale thermal energy storage, thermal management of electronics, etc.

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Advanced Phase Change Composite by Thermally Annealed Defect-Free Graphene for Thermal Energy Storage

Cited by 121 publications

References 47 publications

Graphene nanoplatelet-fly ash based geopolymer composites

Graphene nanoplatelet-fly ash based geopolymer composites

Nanoconfinement of phase change materials within carbon aerogels: phase transition behaviours and photo-to-thermal energy storage

High‐Performance Thermally Conductive Phase Change Composites by Large‐Size Oriented Graphite Sheets for Scalable Thermal Energy Harvesting

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